1
One Paper Time: 3 Hours 70 Marks
Unit I Electrostatics 08
Unit II Current Electricity 07
Unit III Magnetic effect of current & Magnetism 08
Unit IV Electromagnetic Induction and Alternating current 08
Unit V Electromagnetic Waves 03
Unit VI Optics 14
Unit VII Dual Nature of Matter 04
Unit VIII Atoms and Nuclei 06
Unit IX Electronic Devices 07
Unit X Communication Systems 05
Total 70
The question paper will include value based question(s) to the extent of 3-5 marks.
Unit I: Electrostatics (Periods 25) Electric Charges; Conservation of charge, Coulomb’s law-force between two point
charges, forces between multiple charges; superposition principle and continuous
charge distribution.
Electric field, electric field due to a point charge, electric field lines, electric dipole,
electric field due to a dipole, torque on a dipole in uniform electric fleld.
Annexure 'H'
2
Electric flux, statement of Gauss’s theorem and its applications to find field due to
infinitely long straight wire, uniformly charged infinite plane sheet and uniformly
charged thin spherical shell (field inside and outside).
Electric potential, potential difference, electric potential due to a point charge, a dipole
and system of charges; equipotential surfaces, electrical potential energy of a system of
two point charges and of electric dipole in an electrostatic field.
Conductors and insulators, free charges and bound charges inside a conductor.
Dielectrics and electric polarisation, capacitors and capacitance, combination of
capacitors in series and in parallel, capacitance of a parallel plate capacitor with and
without dielectric medium between the plates, energy stored in a capacitor. Van de
Graaff generator.
Unit II: Current Electricity (Periods 22)
Electric current, flow of electric charges in a metallic conductor, drift velocity, mobility
and their relation with electric current; Ohm’s law, electrical resistance, V-I
characteristics (linear and non-linear), electrical energy and power, electrical resistivity
and conductivity. Carbon resistors, colour code for carbon resistors; series and parallel
combinations of resistors; temperature dependence of resistance.
Internal resistance of a cell, potential difference and emf of a cell,combination of cells in
series and in parallel.
Kirchhoff’s laws and simple applications. Wheatstone bridge, metre bridge.
Potentiometer - principle and its applications to measure potential difference and for
comparing emf of two cells; measurement of internal resistance of a cell.
Unit III: Magnetic Effects of Current and Magnetism (Periods 25)
Concept of magnetic field, Oersted’s experiment.
Biot - Savart law and its application to current carrying circular loop.
Ampere’s law and its applications to infinitely long straight wire. Straight and toroidal
solenoids, Force on a moving charge in uniform magnetic and electric fields. Cyclotron.
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Force on a current-carrying conductor in a uniform magnetic field. Force between two
parallel current-carrying conductors-definition of ampere. Torque experienced by a
current loop in uniform magnetic field; moving coil galvanometer-its current sensitivity
and conversion to ammeter and voltmeter.
Current loop as a magnetic dipole and its magnetic dipole moment. Magnetic dipole
moment of a revolving electron. Magnetic field intensity due to a magnetic dipole (bar
magnet) along its axis and perpendicular to its axis. Torque on a magnetic dipole (bar
magnet) in a uniform magnetic field; bar magnet as an equivalent solenoid, magnetic
field lines; Earth’s magnetic field and magnetic elements. Para-, dia- and ferro -
magnetic substances, with examples. Electromagnets and factors affecting their
strengths. Permanent magnets.
Unit IV: Electromagnetic Induction and Alternating Currents (Periods 20)
Electromagnetic induction; Faraday’s laws, induced emf and current; Lenz’s Law, Eddy
currents. Self and mutual induction.
Alternating currents, peak and rms value of alternating current/voltage; reactance and
impedance; LC oscillations (qualitative treatment only), LCR series circuit, resonance;
power in AC circuits, wattless current.
AC generator and transformer.
Unit V: Electromagnetic waves (Periods 4)
Need for displacement current, Electromagnetic waves and their characteristics
(qualitative ideas only).Transverse nature of electromagnetic waves.
Electromagnetic spectrum (radio waves, microwaves, infrared, visible, ultraviolet, X-
rays, gamma rays) including elementary facts about their uses.
Unit VI: Optics (Periods 30)
Reflection of light, spherical mirrors, mirror formula. Refraction of light, total internal
reflection and its applications, optical fibres, refraction at spherical surfaces, lenses, thin
lens formula, lens-maker’s formula. Magnification, power of a lens, combination of thin
lenses in contact combination of a lens and a mirror. Refraction and dispersion of light
through a prism.
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Scattering of light - blue colour of sky and reddish apprearance of the sun at sunrise
and sunset.
Optical instruments : Human eye, image formation and accommodation correction of
eye defects (myopia, hypermetropia) using lenses. Microscopes and astronomical
telescopes (reflecting and refracting) and their magnifying powers.
Wave optics: Wave front and Huygen's principle, relection and refraction of plane wave
at a plane surface using wave fronts. Proof of laws of reflection and refraction using
Huygen's principle. Interference Young's double slit experiment and expression for
fringe width, coherent sources and sustained interference of light. Diffraction due to a
single slit, width of central maximum. Resolving power of microscopes and
astronomical telescopes. Polarisation, plane polarised light Brewster's law, uses of plane
polarised light and Polaroids.
Unit VII: Dual Nature of Matter and Radiation (Periods 8)
Dual nature of radiation. Photoelectric effect, Hertz and Lenard’s observations;
Einstein’s photoelectric equation-particle nature of light.
Matter waves-wave nature of particles, de Broglie relation. Davisson-Germer
experiment (experimental details should be omitted; only conclusion should be
explained).
Unit VIII: Atoms & Nuclei (Periods 18)
Alpha-particle scattering experiment; Rutherford’s model of atom; Bohr model, energy
levels, hydrogen spectrum.
Composition and size of nucleus, atomic masses, isotopes, isobars; isotones.
Radioactivity-alpha, beta and gamma particles/rays and their properties; radioactive
decay law. Mass-energy relation, mass defect; binding energy per nucleon and its
variation with mass number; nuclear fission, nuclear fusion.
Unit IX: Electronic Devices (Periods 18)
Energy bands in solids (Qualitative ideas only) conductors, insulator and
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semiconductors; semiconductor diode – I-V characteristics in forward and reverse bias,
diode as a rectifier; I-V characteristics of LED, photodiode, solar cell, and Zener diode;
Zener diode as a voltage regulator. Junction transistor, transistor action, characteristics
of a transistor, transistor as an amplifier (common emitter configuration) and oscillator.
Logic gates (OR, AND, NOT, NAND and NOR). Transistor as a switch.
Unit X: Communication Systems (Periods 10)
Elements of a communication system (block diagram only); bandwidth of signals
(speech, TV and digital data); bandwidth of transmission medium. Propagation of
electromagnetic waves in the atmosphere, sky and space wave propagation. Need for
modulation. Production and detection of an amplitude-modulated wave.
Practicals
Every student will perform atleast 15 experiments (7 from section A and 8 from Section
B) The activities mentioned here should only be for the purpose of demonstration. One
Project of three marks is to be carried out by the students.
B. Evaluation Scheme for Practical Examination: Total Periods : 60
Two experiments one from each section 8+8 Marks
Practical record (experiments & activities) 6 Marks
Project 3 Marks
Viva on experiments & project 5 Marks
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Total 30 Marks
SECTION A
Experiments
(Any 7 experiments out of the following to be performed by the students)
1. To find resistance of a given wire using metre bridge and hence determine the
specific resistance of its material
2. To determine resistance per cm of a given wire by plotting a graph of potential
difference versus current.
3. To verify the laws of combination (series/parallel) of resistances using a metre
bridge.
4. To compare the emf of two given primary cells using potentiometer.
5. To determine the internal resistance of given primary cell using potentiometer.
6. To determine resistance of a galvanometer by half-deflection method and to find
its figure of merit.
7. To convert the given galvanometer (of known resistance and figure of merit) into
an ammeter and voltmeter of desired range and to verify the same.
8. To find the frequency of the a.c. mains with a sonometer.
Activities
1. To measure the resistance and impedance of an inductor with or without iron core.
2. To measure resistance, voltage (AC/DC), current (AC) and check continuity of a
given circuit using multimeter.
3. To assemble a household circuit comprising three bulbs, three (on/off) switches, a
fuse and a power source.
4. To assemble the components of a given electrical circuit.
5. To study the variation in potential drop with length of a wire for a steady current.
6. To draw the diagram of a given open circuit comprising at least a battery,
resistor/rheostat, key, ammeter and voltmeter. Mark the components that are not
connected in proper order and correct the circuit and also the circuit diagram.
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SECTION B
Experiments
(Any 8 experiments out of the following to be performed by the students)
1. To find the value of v for different values of u in case of a concave mirror and to
find the focal length.
2. To find the focal length of a convex mirror, using a convex lens.
3. To find the focal length of a convex lens by plotting graphs between u and v or
between 1/u and 1/v.
4. To find the focal length of a concave lens, using a convex lens.
5. To determine angle of minimum deviation for a given prism by plotting a graph
between angle of incidence and angle of deviation.
6. To determine refractive index of a glass slab using a travelling microscope.
7. To find refractive index of a liquid by using (i) concave mirror, (ii) convex lens and
plane mirror.
8. To draw the I-V characteristic curve of a p-n junction in forward bias and reverse
bias.
9. To draw the characteristic curve of a zener diode and to determine its reverse break
down voltage.
10. To study the characteristic of a common - emitter npn or pnp transistor and to find
out the values of current and voltage gains.
Activities (For the purpose of demonstration only)
1. To identify a diode, an LED, a transistor, and IC, a resistor and a capacitor from
mixed collection of such items.
2. Use of multimeter to (i) identify base of transistor (ii) distinguish between npn and
pnp type transistors (iii) see the unidirectional flow of current in case of a diode and
an LED (iv) check whether a given electronic component (e.g. diode, transistor or
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IC) is in working order.
3. To study effect of intensity of light (by varying distance of the source) on an L.D.R.
4. To observe refraction and lateral deviation of a beam of light incident obliquely on
a glass slab.
5. To observe polarization of light using two Polaroids.
6. To observe diffraction of light due to a thin slit.
7. To study the nature and size of the image formed by (i) convex lens (ii) concave
mirror, on a screen by using a candle and a screen (for different distances of the
candle from the lens/ mirror).
8. To obtain a lens combination with the specified focal length by using two lenses
from the given set of lenses.
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SUGGESTED INVESTIGATORY PROJECTS
CLASS XII
1 To study various factors on which the internal resistance/emf of a cell depends.
2. To study the variations, in current flowing, in a circuit containing a LDR, because
of a variation.
(a) in the power of the incandescent lamp, used to 'illuminate' the LDR. (Keeping
all the lamps at a fixed distance).
(b) in the distance of a incandescent lamp, (of fixed power), used to 'illuminate'
the LDR.
3. To find the refractive indices of (a) water (b) oil (transparent) using a plane mirror,
a equiconvex lens, (made from a glass of known refractive index) and an
adjustable object needle.
4. To design an appropriate logic gate combinatin for a given truth table.
5. To investigate the relation between the ratio of
(i) output and input voltage and
(ii) number of turns in the secondary coil and primary coil of a self designed
transformer.
6. To investigate the dependence, of the angle of deviation, on the angle of incidence,
using a hollow prism filled, one by one, with different transparent fluids.
7. To estimate the charge induced on each one of the two identical styro foam (or
pith) balls suspended in a vertical plane by making use of Coulomb's law.
8. To set up a common base transistor circuit and to study its input and output
characteristic and to calculate its current gain.
9. To study the factor, on which the self inductance, of a coil, depends, by observing
the effect of this coil, when put in series with a resistor/(bulb) in a circuit fed up by
an a.c. source of adjustable frequency.
10. To construct a switch using a transistor and to draw the graph between the input
and output voltage and mark the cut-off, saturation and active regions.
11. To study the earth's magnatic field using a tangent galvanometer.
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SAMPLE QUESTION PAPER
PHYSICS (042)
CLASS XII (2013-14)
Design of Question paper
Time: 3 hrs. Maximum Marks: 70
The weightage of the distribution of marks over different dimensions of the question
paper shall be as follows
A. Weightage to different units
S. No. Unit Marks
1. Electrostatics 08
2. Current Electricity 07
3. Magnetic Effects of current and Magnetism 08
4. Electromagnetic Induction and Alternating
Current
08
5. Electromagnetic waves 03
6. Optics 14
7. Dual Nature of Radiation and Matter 04
8. Atoms and Nuclei 06
9. Electronic Devices 07
10 Communication Systems 05
Total 70
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B. Weightage to form of questions
S. No. Type of question Marks per
Question
Total
number of
Questions
Total
marks
1 VSA 1 8 8
2 SA I 2 10 20
3 SA II/Value Based
Question
3 9 27
4 LA 5 3 15
Total 30 70
C. Typology of Questions
S. No. Typology Weightage in
marks
Weightage in
percentage
1 Knowledge Based 14 20%
2 Conceptual Understanding 21 30%
3 Inferential Type 14 20%
4 Reasoning Based 11 15%
5 Skill Based 10 15%
Total 70 100%
D. Weightage to Numericals
The question paper will include numerical questions of 12-15 marks.
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E. Scheme of options
There will be no overall choice. However, internal choice in any one question of
two marks, any one question of three marks and all the three questions of five
marks weightage has been provided.
F. Difficulty level of questions
S. No. Estimated difficulty level Percentage of marks
1 Easy 15
2 Average 70
3 Difficult 15
The question paper will include value based question(s) to the extent of 3–5 marks.
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PHYSICS
CLASS - XII
SAMPLE PAPER
BLUE PRINT
S. No. Unit VSA
(1 mark)
SA I (2 marks)
SA II/VBQ* (3 marks)
LA (5 marks)
TOTAL
1. Electrostatics 1 (1) 4 (2) 3 (1) 8 (4)
2. Current Electricity
2 (2) 2 (1) 3 (1) 7 (4)
3. Magnetic effect of current & Magnetism
4(2) 3 (1) 8 (4)
4. Electromagnetic Induction and Alternating Current
1 (1) 2 (1) 5 (1) 8 (3)
5. Electromagnetic Waves
3 (1)
6. Optics 1 (1) 2 (1) 6 (2) 5 (1) 14 (5)
7. Dual nature of Radiation and matter
4 (2) 4 (2)
8. Atoms and Nuclei
3 (1) 3 (1)*
6 (2)
9. Electronic Devices
2 (1) 5 (1) 7 (2)
10. Communication Systems
2 (2) 3 (1) 5 (3)
Total 8 (8) 20 (10) 27 (9) 15 (3) 70 (30)
The question paper will include value based question(s) to the extent of 3–5 marks.
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PHYSICS CLASS-XII
SAMPLE PAPER-1
Q1. A magnet is being moved towards a coil with a uniform speed as shown in the
figure. State the direction of the induced current in the resistor R. 1
Q2. A square coil, OPQR, of side a, carrying a current I, is placed in the Y-Z plane as
shown here. Find the magnetic moment associated with this coil. 1
Q3. Give one example each of a ‘system’ that uses the
(i) Sky wave (ii) Space wave
mode of propagation 1
Q4. A concave mirror, of aperture 4cm, has a point object placed on its principal axis
at a distance of 10cm from the mirror. The image, formed by the mirror, is not
likely to be a sharp image. State the likely reason for the same. 1
Q5. Two dipoles, made from charges q and Q, respectively, have equal dipole
moments. Give the (i) ratio between the ‘separations’ of the these two pairs of
charges (ii) angle between the dipole axis of these two dipoles. 1
15
Q6. The graph, shown here, represents the V-I characteristics of a device. Identify the
region, if any, over which this device has a negative resistance. 1
Q7. Define the term ‘Transducer’ for a communication system. 1
Q8. State the steady value of the reading of the ammeter in the circuit shown below.
1
Q9. The following table gives data about the single slit diffraction experiment:
Wave length of Light Half Angular width of
the principal maxima
p q
Find the ratio of the widths of the slits used in the two cases. Would the ratio of
the half angular widths of the first secondary maxima, in the two cases, be also
equal to q? 2
Q10. N spherical droplets, each of radius r, have been charged to have a potential V
each. If all these droplets were to coalesce to form a single large drop, what
would be the potential of this large drop?
(It is given that the capacitance of a sphere of radius r equals 4 kr.)
16
OR
Two point charges, q1 and q2, are located at points (a, o, o) and (o, b, o)
respectively. Find the electric field, due to both these charges, at the point,
(o, o, c). 2
Q11. When a given photosensitive material is irradiated with light of frequency , the
maximum speed of the emitted photoelectrons equals max. The square of max,
i.e., max2, is observed to vary with , as per the graph shown here.
Obtain expressions for
(i) Planck’s constant, and
(ii) The work function of the given photosensitive material,
in terms of the parameters n and the mass, m, of the electron.
Q12. For the circuit shown here, would the balancing length increase, 2
decrease or remain the same, if
(i) R1 is decreased
(ii) R2 is increased
without any other change, (in each case) in the rest of the circuit. Justify your
answers in each case.
17
Q13. Find the P.E. associated with a charge ‘q’ if it were present at the point P with
respect to the ‘set-up’ of two charged spheres, arranged as shown. Here O is the
mid-point of the line O1 O2. 2
Q14. An athlete peddles a stationary tricycle whose pedals are attached to a coil
having 100 turns each of area 0.1m2. The coil, lying in the X-Y plane, is rotated,
in this plane, at the rate of 50 rpm, about the Y-axis, in a region where a
uniform magnetic field, = (0.01) tesla, is present. Find the
(i) maximum emf (ii) average e.m.f
generated in the coil over one complete revolution. 2
Q15. A monochromatic source, emitting light of wave length, 600 nm, has a power
output of 66W. Calculate the number of photons emitted by this source in
2 minutes. 2
Q16. For the circuit shown here, find the
current flowing through the 1 resistor.
Assume
that the two diodes, D1 and D2, are ideal
diodes.
Q17. The following table shows the range of values of susceptibility and relative
magnetic permeability of two different type of magnetic substances
Substance Susceptibility Magnetic Permeability
X -1 to 0 0 to 1
Y >> 1 >> 1
2
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(a) Identify the type of magnetic materials X and Y.
(b) How does the susceptibility and permeability of X and Y vary with rise in
temperature? 2
Q18. Two wires are aligned parallel to each other. One is carrying an electric current
and the other is not. Will there be any kind of electromagnetic force between
the two? Give reason for your answer. 2
Q19. The galvanometer, in each of the two given circuits, does not show any
deflection. Find the ratio of the resistors R1 and R2, used in these two
circuits. 3
Q20. The electron, in a hydrogen atom, initially in a state of quantum number n1
makes a transition to a state whose excitation energy, with respect to the
ground state, is 10.2 eV. If the wavelength, associated with the photon emitted
in this transition, is 487.5 mm, find the
(i) energy in ev, and (ii) value of the quantum number, n1 of the electron in
its initial state. 3
OR
The spectrum of a star in the visible and the ultraviolet region was observed
and the wavelength of some of the lines that could be identified were found to
be
824 Å, 970 Å, 1120 Å, 2504 Å, 5173 Å, 6100 Å.
Which of these lines cannot belong to hydrogen atom spectrum? Support your
answer with suitable calculations.
Take Rydberg constant R = 1.03 X 107 m-1 and = 970 Å.
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Q21. Three identical polaroid sheets P1, P2, and P3 are oriented so that the (pass) axis
of P2 and P3 are inclined at angles of 600
and 900, respectively, with respect to
the (pass) axis of P1. A monochromatic
source, S, of intensity I0, is kept in front
of the polaroid sheet P1. Find the
intensity of this light, as observed by
observers O1, O2, and O3, positioned as
shown below.
Q22. A fine pencil of -particles, moving with a speed , enters a region (region I),
where a uniform electric and a uniform magnetic field are both present. These
-particles then move into region II where only the magnetic field, (out of the
two fields present in region I), exists. The path of the -particles, in the two
regions, is as shown in the figure.
(i) State the direction of the magnetic field.
(ii) State the relation between ‘E’ and ‘B’ in region I.
(iii) Drive the expression for the radius of the circular path of the -particle in
region II.
If the magnitude of magnetic
field, in region II, is changed
to n times its earlier value,
(without changing the
magnetic field in region I)
find the factor by which the radius of this circular path would change. 3
Q23. Draw an appropriate ray diagram to show the passage of a ‘white ray’, incident
on one of the two refracting faces of a prism. State the relation for the angle of
deviation, for a prism of small refracting angle.
It is known that the refractive index, , of the material of a prism, depends on
the wavelength , , of the incident radiation as per the relation
= A +
20
where A and B are constants. Plot a graph showing the dependence of on
and identify the pair of variables, that can be used here, to get a straight line
graph. 3
Q24. Excessively large amount of energy is released in an uncontrolled way in a
nuclear bomb explosion. Some scientists have expressed fear that a future
nuclear war on Earth would be followed by a severe ‘nuclear winter’ with a
devasting effect on life on Earth. 3
Answer the following questions based on above possible scenario:
a) Name the basic principle responsible for release of large amount of energy
in a nuclear bomb explosion. How will the nuclear bomb explosion result
in ‘nuclear winter’?
b) Which two human values need to be promoted in individuals so that such
a situation of nuclear winter does not arise?
c) Suggest any one method to promote these values in school students.
Q25. The modulation index of an amplitude modulated wave is 0.5. What does it
mean?
Calculate the modulation index for an AM wave for which the maximum
amplitude is ‘a’ while the minimum amplitude is ‘b’. 3
Q26. The capacitors C1, and C2, having plates of area A each, are connected in series,
as shown. Campare the capacitance of this combination with the capacitor C3,
again having plates of area A each, but ‘made up’ as shown in the figure. 3
3
Q27. (a) Write the formula for the velocity of light in a material medium of relative
permittivity r and relative magnetic permeability r. 1
21
(b) The following table gives the wavelength range of some constituents of
the electromagnetic spectrum.
Select the wavelength range, and name the (associated) electromagnetic waves,
that are used in
(i) Radar systems for Aircraft navigation
(ii) Earth satellites to observe growth of crops. 2
Q28. A conducting rod XY slides freely on two parallel rails, A and B, with a
uniform velocity ‘V’. A galvanometer ‘G’
is connected, as shown in the figure and
the closed circuit has a total resistance ‘R’.
A uniform magnetic field, perpendicular
to the plane defined by the rails A and B
and the rod XY (which are mutually
perpendicular), is present over the region,
as shown.
(a) With key k open:
(i) Find the nature of charges developed at the ends of the rod XY.
(ii) Why do the electrons, in the rod XY, (finally) experience no net force
even through the magnetic force is acting on them due to the motion
of the rod?
(b) How much power needs to be delivered, (by an external agency), to keep
the rod moving at its uniform speed when key k is (i) closed (ii) open?
(c) With key k closed, how much power gets dissipated as heat in the circuit?
State the source of this power.
S.No. Wavelength Range
1. 1mm to 700nm
2. 0.1m to 1mm
3. 400 nm to 1nm
4. < 10 3 nm
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OR
‘Box’ A, in the set up shown below, represents an electric device often
used/needed to supply, electric power from the (ac) mains, to a load.
It is known that Vo < Vi.
(a) Identify the device A and draw its symbol.
(b) Draw a schematic diagram of this electric device. Explain its principle and
working. Obtain an expression for the ratio between its output and input
voltages.
(c) Find the relation between the input and output currents of this device
assuming it to be ideal. 5
Q29. Define the terms ‘depletion layer’ and ‘barrier potential’ for a P-N junction
diode. How does an increase in the doping concentration affect the width of the
depletion region?
Draw the circuit of a full wave rectifier. Explain its working.
OR
Why is the base region of a transistor kept thin and lightly doped?
Draw the circuit diagram of the ‘set-up’ used to study the characteristics of a
npn transistor in its common emitter configuration. Sketch the typical (i) Input
characteristics and (ii) Output characteristics for this transistor configuration.
How can the out put characteristics be used to calculate the ‘current gain’ of the
transistor?
Q30. (i) A thin lens, having two surfaces of radii of curvature r1 and r2, made
from a material of refractive index , is kept in a medium of refractive
index . Derive the Lens Maker’s formula for this ‘set-up’
23
(ii) A convex lens is placed over a plane mirror. A pin is now positioned so
that there is no parallax between the pin and its image formed by this
lens-mirror combination. How can this observation be used to find the
focal length of the convex lens? Give appropriate reasons in support of
your answer.
OR
The figure, drawn here, shows a modified Young’s double slit experimental set
up. If SS2 SS1, = /4,
(i) state the condition for constructive and destructive interference
(ii) obtain an expression for the fringe width.
(iii) locate the position of the central fringe. 5
24
MARKING SCHEME
Q.No. Value point/ expected points Marks Total
1. From X to Y 1 1
2. The magnetic moment, associated with the
coil, is
m = Ia2
1
1
3. (i) Short wave broadcast services
(ii) Television broadcast (or microwave
links or Satellite communication)
½
½
1
4. The incident rays are not likely to be
paraxial.
1 1
5. As qa = Qa’, we have
=
and = 0o
½
½
1
6. Region BC 1 1
7. A ‘transducer’ is any device that converts
one form of energy into another
1 1
8. Zero 1 1
9. Let d and d’ be the width of the slits in the
two cases.
and q =
=
Yes, this ratio would also equal q
½+½
½
½
2
10. Total (initial) charge on all the droplets
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= N x (4 0k r V)
Also N x r3 = R3
R = r
If V’ is the potential of the large drop, we
have
4 R x V’ = N x 4 kr x V
V’ = V = V
OR
We have net = 1 + 2
= 1 + 2
where 1= -a + c
and 2 = -b + c
net =
½
½
½
½
½
½
1
2
2
11. According to Einestein’s Equation:
Kmax = m max = –
This is the equation of a straight line having
a slope 2h/m and an intercept (on the max
axis) of Comparing these, with the
given graph, we get
= or h = and = or =
½
½
½+½
2
12. (i) decreases
(The potential gradient would
increase)
½+½
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(ii) increases
(The terminal p.d across the cell would
increase)
½+½
13. r1 = O,P =
r2 = O2 P =
V =
P.E of charge , q, at P = qV
=
½
½
½
½
2
14. (i) The maximum emf ‘ ’ generated in the
coil is,
= N B A
= N B A 2 f
= [100 x 0.01 x 0.1 x 2 ] V
= V 0.52 V
(ii) The average emf generated in the coil
over one complete revolution = 0
½
1
½
2
15. Energy of one photon = E =
E =
3.3 x 10-19 J
E1 = energy emitted by the source in one
second = 66J
number of photons emitted by the source
in 1s = n = = 2 x 1020
Total number of photons emitted by
½
½
½
2
27
source in 2 minutes
= N = n x 2 x 60
= 2 x 1020 x 120 = 2.4 x 1022 photons
½
16. Diode D1 is forward biased while Diode D2
is reverse biased
Hence the resistances, of (ideal) diodes, D1
and D2, can be taken as zero and infinity,
respectively.
The given circuit can, therefore, be redrawn
as shown in the figure.
Using ohm’s law,
I = A = 2A
current flowing in the 1 resistor, is 2A.
½
½
½
½
2
17. (a) X-Diamagnetic,
Y-Ferromagnetic
(b) X- No change
(c) Y- Decreases with temperature
18. No
- Since there is only one magnetic field,
there is no interaction and hence no
force between the two wires.
19. For circuit 1, we have, (from the Wheatstone
bridge balance condition),
28
R1 = 6
In circuit 2, the interchange of the positions
of the battery and the galvanometer, does
not change the (wheatstone Bridge) balance
condition.
=
or R2 = 4
= =
½
½
½
½
½
½
3
20. In a hydrogen atom, the energy (En) of
electron, in a state, having principal
quantum number ‘n’, is given by
En = eV
E1 = -13.6eV and E2 = -3.4 eV
It follows that the state n=2 has an
excitation energy of 10.2 eV. Hence the
electron is making a transition from n=n1 to
n=2 where (n1>2).
Now En1 – E2 =
But
En1= (-3.4 + 2.55) eV
≃ - 0.85 eV
But we also have En1 = eV
we get n1 = 4
½
½
½
½
½
½
3
29
OR
=
=
If we take n2 = 1 (Lyman series of Hydrogen
Spectrum)
can take values ,
Corresponding to n1 = 2, 3, 4, ……….
Thus, permitted values of are 1293 Å, 1091
Å, 1034 Å, ……., 970 Å.
Similarly if we take n2 = 2 (Balmer Series of
Hydrogen Spectrum), corresponding to n1
= 3, 4, 5, ……
can have values
,
i.e. 6984 Å, 5173 Å, 4619 Å, ………., 3880 Å.
Hence out of the given values
= 824 Å, 1120 Å, 2504 Å, 6100 Å cannot
belong to the hydrogen atom spectrum.
½
½
½
½
½
½
3
21. Intensity observed by
(i) Observer O1 =
(ii) Observer O2 = cos2 60o
½
½
3
30
=
(iii) Observer O3 = cos2 (90o-60o)
= x =
½
1
½
22. (i) The magnetic field is perpendicular to
the plane of page and is directed
inwards
(ii) In region I
=
qE = q B
E = B
(iii) In region II
= q B r =
Substituting the value of , we get
r =
Let B’ (=nB) denote the new magnetic
field in region II. If r’ is the radius of
the circular path now, we have
r1 = =
Hence radius of the circular path,
would decrease by a factor n.
½
½
½
½
½
½
3
23. See (fig 9.25, Page 332 Part II NCERT)
For a small angled prism, of refracting angle
:
Angle of deviation = where is
1
½
31
the refractive index of the material of the
prism.
To get a straight line graph, we need to use
and as the pair of variables.
1
½
3
24. a) - Uncontrolled nuclear chain
reaction.
- The thick smoke produced due to
nuclear explosion would perhaps
cover substantial parts of the sky
preventing solar light from
reaching many parts of the Earth
resulting in lowering of
atmospheric temperature.
b) - International understanding and
Brotherhood.
- Love for humanity/non violence
c) - Group discussion for value
clarification
- Vigorous campaign for spreading
awareness using mass media.
½
½
½
½
½
3
25. It means that the ratio of peak value of
the modulating signal to the peak
2
32
value of carrier wave is 0.5.
If Am is the peak value of modulating
signal and Ac is the peak value of
carrier wave.
We have a = Ac + Am
and b = Ac – Am
Thus, Ac = and Am =
Therefore modulation index
=
1
3
26. We have C1 =
and C2 =
Ceq = =
Now, capacitor C3 can be considered as
made up of two capacitors C1 and C2, each
of plate area A and separation d, connected
in series.
We have : C1’ =
and C2’ =
C3 = =
= 1
Hence net capacitance of the combination is
equal to that of C3.
½
½
½
½
½
½
3
33
27. (a) We have =
(b) (i) Wavelength range: [0.1m to 1mm]
(Microwaves)
(ii) Wavelength range: [1mm to 700
nm] (Infrared waves)
½+½
½+½
½+½
3
28. (a)
(i) X : negative , Y: positive
(ii) Magnetic force, Fm, experienced
by the moving electrons, gets
balanced by the electric force due
to the electric field, caused by the
charges developed at the ends of
the rod. Hence net force on the
electrons, inside the rod, (finally)
become zero.
(b) The power, that needs to be delivered
by the external agency, when key k is
closed, is
P=FmV = (I l B)V = .lBV
= B2l2V2/R
When k is open, there is an induced
emf, but no induced current. Hence
power that needs to be delivered is
zero.
(c) Power, dissipated as heat
= i2 R =
The source of this power is the
mechanical work done by the external
agency.
½
1+½
½+½
½
½+½
½
5
34
OR
(a) Step down transformer.
(b) Diagram
Principle
Working
Obtaining the expression
(c) Input power = output power
Vp iP = Vs is
= =
½
½
½
½
½
2
½
5
29. The space charge region, on either side of
the junction (taken together), is known as
the depletion layer.
The p.d across the depletion layer is known
as the barrier potential
The width of the depletion region decreases
with an increase in the doping
concentraction.
The circuit of a full-wave rectifier is shown
below.
½
½
½
1½
5
35
Working details
OR
The base region of a transistor is thin and
lightly doped so that the base current (IB) is
very small compared to emitter current (IE).
2
1
1
1
1
5
36
The current gain of a transistor in
common emitter configuration is
=
IC and IB can be obtained, from the two
curves, in the output characteristics.
1
30.
(i) Diagram
Derivation
(ii) The rays must fall normally on the
plane mirror so that the image of the
pin coincides with itself
Hence rays, like CA and DB, form a
parallel beam incident on the lens.
P is the position of the focus of the
lens
Distance OP equals the focal length
of the lens
OR
1
2½
½
½
½
1
5
37
= initial path different between S1 and S2
= SS2 – SS1 =
= S2P–S1P = path difference between
disturbance from S1 and S2, at point P
=
= Total path difference between the two
disturbances at P
= + = +
For constructive interference:
= = n ; n = 0, 1, 2,….
= (n- ) …(i)
For destructive interference
= (2n-1) . . . (ii)
–
= fringe width = yn+1 –yn =
The position Yo of central fringe is obtained
by putting n=o in Eqn (i). Therefore,
yo = -
[Negative sign shows that the central fringe
is obtained at a point below the (central)
point O.]
½
½
1
1
1
5